Vehicle assembly with independent electric wheel motors for electric hybrid vehicles

ABSTRACT

A vehicle drive assembly is provided. The vehicle drive assembly includes an engine, a transmission operably coupled with the engine, an output shaft operably coupled with the transmission, a differential operably coupled with the output shaft, an axle shaft rotatably coupled to the differential, at least one wheel selectively coupled to the axle shaft via a rotatable axle stub, an electric wheel motor operably coupled to the at least one wheel via the rotatable axle stub, and a coupling device operably coupled with the electric wheel motor for selectively coupling the axle stub with the axle shaft.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention generally relates to drive systems for vehicles, and moreparticularly, to a drive system having electric wheel motors mounted toeach wheel of the vehicle.

2. Discussion of the Related Art

Generally, vehicles may be powered by an internal combustion engine orone or more electric motors. Some so-called hybrid vehicles include acombination of an internal combustion engine and electric motor power.Such hybrid vehicles sometimes include parallel drive systems thatprovide propulsion modes from the electric motor, internal combustionengine, or both.

Typically, the mechanical coupling that allows selection betweenelectrical or internal combustion power is mounted directly to theinternal combustion engine, vehicle transmission, or a so-calledsummation gearbox that combines the electric drive with the mechanicaldrive. Such arrangements allow for a controller or the vehicle operatorto select between the electrical power and the internal combustion powerfor driving the vehicle.

A major drawback of previous vehicles that combine the electric drivewith the mechanical drive is that there is little modularity in design.The electric motor or drive may be bulky and large. Additionally, thetransmission required to operate both the electric motor and internalcombustion engine is complex in design.

The present invention provides an arrangement that allows for adecentralized or modular design where an electric wheel motor is mountedat each wheel. This allows for improved modularity, smaller parts,improved safety, and reduced maintenance costs.

SUMMARY OF THE INVENTION

Features and advantages of the invention will be set forth in thedescription which follows, and in part will be apparent from thedescription, or may be learned by practice of the invention. Theobjectives and other advantages of the invention will be realized andattained by the structure particularly pointed out in the writtendescription and claims hereof as well as the appended drawings.

In accordance with an embodiment, a vehicle drive assembly is provided.The vehicle drive assembly includes an engine, a transmission operablycoupled with the engine, an output shaft operably coupled with thetransmission, wherein the output shaft rotates according to an operationbetween the engine and the transmission, a differential operably coupledwith the output shaft, an axle shaft rotatably coupled to thedifferential, wherein the axle shaft is rotated by the differential whenthe output shaft rotates, at least one wheel selectively coupled to theaxle shaft via a rotatable axle stub wherein the at least one wheel isrotated according to a rotation of the axle shaft when the axle shaft isoperably coupled to the axle stub, an electric wheel motor operablycoupled to the at least one wheel via the rotatable axle stub, whereinthe at least one wheel is rotated when the electric wheel motor providesa torque to the rotatable axle stub, and a coupling device operablycoupled with the electric wheel motor for selectively coupling the axlestub with the axle shaft, wherein when the axle shaft is not coupled tothe axle stub, the at least one wheel cannot be rotated by the enginevia the axle shaft.

In one feature, the vehicle drive assembly further includes a powerstorage medium providing power to the electric wheel motor.

In another feature, the vehicle drive assembly further includes acontroller for controlling the vehicle drive assembly according to atleast one of a first mode wherein the coupling device uncouples the axleshaft from the axle stub and the electric wheel motor alone providestorque to the axle stub to rotate the at least one wheel, a second modewherein the engine alone provides torque to the axle stub via the axleshaft to rotate the at least one wheel, and a third mode wherein boththe electric wheel motor and engine provide torque to the axle stub torotate the at least one wheel. Furthermore, the controller controls theoperation of the engine in a fourth mode such that the engine functionsas a generator for a power storage medium providing power to theelectric wheel motor. Moreover, the controller controls the vehicledrive assembly according to the first mode when a vehicle speed is lessthan a predetermined speed. Additionally, the controller controls thevehicle drive assembly according to the second mode and third mode whena vehicle speed is greater than a predetermined speed.

In yet another feature, the controller controls the amount of torqueoutput from the electric wheel motor. Furthermore, the amount of torqueoutput from the electric wheel motor varies according to at least one ofa driver selection, a road condition, and a driving condition.

In still yet another feature, the electric wheel motor supplies a forceto the axle stub to reduce the rotation of the at least one wheel in thefirst mode, second mode, or third mode. Additionally, the electric wheelmotor further includes a planetary gearset for operation in the thirdmode.

In one embodiment, a vehicle drive assembly is provided. The vehicledrive assembly includes an engine, a transmission operably coupled withthe engine a transfer unit operably associated with the transmission, arear output shaft operably coupled with the transfer unit, wherein therear output shaft rotates according to an operation between the engine,the transmission, and the transfer unit, a front output shaft operablycoupled with the transfer unit, wherein the front output shaft rotatesaccording to an operation between the engine, the transmission, and thetransfer unit, a front differential operably coupled with the frontoutput shaft, a rear differential operably coupled with the rear outputshaft, a front axle shaft rotatably coupled to the front differential,wherein the front axle shaft is rotated by the front differential whenthe front output shaft rotates, a rear axle shaft rotatably coupled tothe rear differential, wherein the rear axle shaft is rotated by therear differential when the rear output shaft rotates, at least one frontwheel selectively coupled to the front axle shaft via a front rotatableaxle stub wherein the at least one front wheel is rotated according to arotation of the front axle shaft when the front axle shaft is operablycoupled to the front axle stub, at least one rear wheel selectivelycoupled to the rear axle shaft via a rear rotatable axle stub whereinthe at least one rear wheel is rotated according to a rotation of therear axle shaft when the rear axle shaft is operably coupled to the rearaxle stub, an electric wheel motor operably coupled to the at least onefront wheel via the front rotatable axle stub, wherein the at least onefront wheel is rotated when the electric wheel motor provides a torqueto the front rotatable axle stub, and a coupling device operably coupledwith the electric wheel motor for selectively coupling the front axlestub with the front axle shaft, wherein when the front axle shaft is notcoupled to the front axle stub, the at least one front wheel cannot berotated by the engine via the front axle shaft.

In another embodiment, a vehicle drive assembly is provided. The vehicledrive assembly includes an engine, a transmission operably coupled withthe engine, a transfer unit operably associated with the transmission, arear output shaft operably coupled with the transfer unit, wherein therear output shaft rotates according to an operation between the engine,the transmission, and the transfer unit, a front output shaft operablycoupled with the transfer unit, wherein the front output shaft rotatesaccording to an operation between the engine, the transmission, and thetransfer unit, a front differential operably coupled with the frontoutput shaft, a rear differential operably coupled with the rear outputshaft, a front axle shaft rotatably coupled to the front differential,wherein the front axle shaft is rotated by the front differential whenthe front output shaft rotates, a rear axle shaft rotatably coupled tothe rear differential, wherein the rear axle shaft is rotated by therear differential when the rear output shaft rotates, at least one frontwheel selectively coupled to the front axle shaft via a front rotatableaxle stub wherein the at least one front wheel is rotated according to arotation of the front axle shaft when the front axle shaft is operablycoupled to the front axle stub, at least one rear wheel selectivelycoupled to the rear axle shaft via a rear rotatable axle stub whereinthe at least one rear wheel is rotated according to a rotation of therear axle shaft when the rear axle shaft is operably coupled to the rearaxle stub, an electric wheel motor operably coupled to the at least onerear wheel via the rear rotatable axle stub, wherein the at least onerear wheel is rotated when the electric wheel motor provides a torque tothe rear rotatable axle stub, and a coupling device operably coupledwith the electric wheel motor for selectively coupling the rear axlestub with the rear axle shaft, wherein when the rear axle shaft is notcoupled to the rear axle stub, the at least one rear wheel cannot berotated by the engine via the rear axle shaft.

These and other embodiments will also become readily apparent to thoseskilled in the art from the following detailed description of theembodiments having reference to the attached figures, the invention notbeing limited to any particular embodiment disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects, features, and advantages of the presentinvention will become more apparent upon consideration of the followingdescription of preferred embodiments, taken in conjunction with theaccompanying drawing figures, wherein:

FIG. 1 illustrates a vehicle incorporating a vehicle drive system inaccordance with one embodiment of the present invention.

FIG. 2 illustrates a first mode of operation of the vehicle drive systemin accordance with one embodiment of the present invention.

FIG. 3 illustrates a second mode of operation of the vehicle drivesystem in accordance with one embodiment of the present invention.

FIG. 4 illustrates a third mode of operation of the vehicle drive systemin accordance with one embodiment of the present invention.

FIG. 5 illustrates the vehicle drive system in accordance with oneembodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the following detailed description, reference is made to theaccompanying drawing figures which form a part hereof, and which show byway of illustration specific embodiments of the invention. It is to beunderstood by those of ordinary skill in this technological field thatother embodiments may be utilized, and structural, electrical, as wellas procedural changes may be made without departing from the scope ofthe present invention. Wherever possible, the same reference numberswill be used throughout the drawings to refer to the same or similarparts.

FIG. 1 illustrates an example of a vehicle 10 with which electric wheelmotors 17 may be used in accordance with embodiments of the presentinvention. In one embodiment, an internal combustion engine 11 providesa driving torque to wheels 13 through a conventional transmission system12 which is associated with an output shaft 15 and a differential 16.The wheels 13 are supported by a coaxial axle shaft 14 which is coupledto the differential 16. The wheels 13 are also coupled with an electricwheel motor 17.

FIGS. 2-4 are perspective diagrams of a vehicle drive assembly with anelectric wheel motor 17 coupled with wheels 13, 18. As shown in FIG.2-4, the vehicle drive assembly includes an internal combustion engine11 with a conventional transmission system 12. The internal combustionengine 11 may provide driving torque to the wheels 13 via output shaft15 which is coupled to the transmission 12. The output shaft 15 providestorque to the axle shaft 22 via the differential 16. The axle shaft 22may be selectively coupled to the axle stub 23 via a clutch unit 25which is housed in the electric wheel motor 17. The coupled axle shaft22 and axle stub 23 comprise the coaxial shaft 14. The differential 16may be a conventional differential for providing the desired torquedistribution to the wheels 13. The output shaft 15 may provide drivingtorque to wheels 13 depending on the operative condition of the clutchunit 25, which selectively couples the axle shaft 22 to the axle stub23.

The vehicle drive assembly also includes electric wheel motors 17respectively coupled with wheels 13, 18. In this example the vehicleassembly includes four wheels, however, alternate embodiments of thepresent invention may include more than four wheels, wherein each wheelmay be coupled to an electric wheel motor. Each electric wheel motor 17may provide torque to the respectively coupled wheel via an axle stub 23coupled between each wheel 13, 18 and electric wheel motor 17. Acontroller 20 controls operation of each electric wheel motor 17. Thecontroller 20 is connected to each electric wheel motor 17 via a controlline 21. A power storage unit 28 provides the electricity to power eachelectric wheel motor 17. In this example, the power storage unit 28 mayconnect with each electric wheel motor 17 via the control line 21. In analternate embodiment, the power storage unit 28 may connect with eachelectric wheel motor 17 via a power line that is separate from thecontrol line 21. The power storage unit 28 may be capable of short-termand high-load storage of electricity.

FIG. 2 shows the operation of selected components of a vehicle drivesystem in a first operating mode where torque distribution is performedby the electric wheel motors 17 in accordance with one embodiment of thepresent invention. Under certain conditions it may be desirable toprovide torque for rotating the wheels 13, 18 exclusively from theelectric wheel motors 17. For example, it may be preferable for theelectric wheel motors 17 to exclusively provide torque for rotating thewheels 13, 18 when the vehicle is operated at a speed less than apredetermined speed. The predetermined speed may be set by amanufacturer or a user. Additionally, the predetermined speed may be setaccording to driving conditions, driving habits, road conditions, or acombination thereof.

As shown in FIG. 2, the power storage unit 28 provides power to eachelectric wheel motor 17 via the control unit line 21. When the electricwheel motors 17 have received power from the power storage unit 28, thecontrol unit 20 controls the operation of each electric wheel motor 17.

Each electric wheel motor 17 is coupled to an axle stub 23 which iscoupled to each wheel 13, 18. The control unit 20 controls each electricwheel motor 17 to provide torque to the axle stub 23 which then rotateseach wheel 13, 18. The control unit 20 may vary the amount of torqueapplied to each wheel 13, 18 via the electric wheel motor 17.Preferably, the control unit 20 may vary the amount of torque applied toeach wheel 13, 18 according to at least one of a user selection, adriving condition, a road condition, and a user's driving habits.Additionally, the amount of torque applied to each wheel may be variedto provide the vehicle with various performance functions such as launchcontrol, traction control, stability control, or an anti-lock brakesystem.

In addition to varying the amount of torque applied to each wheel 13,18, the control unit 20 may control each electric wheel motor to reduceor stop the rotation of each respective wheel 13, 18. The control unit20 may control each electric wheel motor 17 to act as a traditionalbrake such that the vehicle 10 using the vehicle drive system of thepresent invention may bypass or eliminate the use of a traditionalbraking mechanism.

In an alternate embodiment of the present invention, each electric wheelmotor 17 may house a planetary transmission (not shown) for providingthe necessary gear reduction between the electric wheel motor 17 and theaxle stub 23. The gear reduction provided by the planetary transmissionprovides desired rotation and torque to the axle stub 23 and allows theelectric wheel motor to operate at an optimal round per minute (RPM)range. The planetary transmission may be controlled by the control unit20 when the vehicle is in the first operating mode.

In accordance with the present invention, while the vehicle operates inthe first operating mode, i.e. when the vehicle is operated at a speedless than the predetermined speed, the control unit 20 controls a clutchunit 25 to un-couple the axle shaft 22 from the axle stub 23. When theaxle shaft 22 is un-coupled from the axle stub 23, the electric wheelmotor 17 is disengaged from the internal combustion engine 11. As aresult of the disengagement, the axle stubs 23 only receive torque fromthe electric wheel motors 17.

FIG. 3 shows the operation of selected components of a vehicle drivesystem in a second operating mode where torque distribution is performedby the internal combustion engine 11 in accordance with one embodimentof the present invention. Under certain conditions it may be desirableto provide torque for rotating the wheels 13, 18 exclusively from theinternal combustion engine 11. For example, it may be preferable for theinternal combustion engine 11 to exclusively provide torque for rotatingwheels 13, 18 when the vehicle is operated at a speed greater than apredetermined speed. The predetermined speed may be set by amanufacturer or a user. Additionally, the predetermined speed may be setaccording to driving conditions, driving habits, road conditions, or acombination thereof.

As shown in FIG. 3, the internal combustion engine 11 causes rotation ofthe output shaft 15 via the transmission system 12. The output shaft 15is connected to the differential 16, which then distributes torque tothe axle shafts 22. The axle shafts 22 are respectively coupled to anaxle stub 23 via a clutch unit 25 in order to rotate the wheels 13.

Preferably, the control unit 20 controls the clutch unit 25 to couplethe axle shafts 22 with the respective axle stub 23 when the vehicle isin the second operating mode, such as when the vehicle is operated at aspeed greater than the predetermined speed. When the axle shaft 22 iscoupled with the axle stub 23, the electric wheel motor 17 isoperatively engaged with the internal combustion engine 11. As a resultof the engagement, the axle stubs 23 are capable of receiving torquefrom the electric wheel motors 17 as well as the internal combustionengine 11. However, as mentioned above, when the vehicle drive system isin the second operating mode, the electric wheel motor 17 preferablydoes not provide torque to the axle stub 23.

Furthermore, although the electric wheel motor 17 does not providetorque to the axle stub 23 in the second operating mode, the controlunit 20 may control each electric wheel motor to reduce or stop therotation of each respective wheel 13, 18. Thus, the control unit 20 maycontrol each electric wheel motor 17 to act as a traditional brake toreplace, complement, or assist the use of a traditional brakingmechanism while the vehicle drive system operates in the secondoperating mode. Also, while in the second operating mode, the internalcombustion engine 11 may act as a generator to produce electricity to bestored in the power storage unit 28 and provided to the electric wheelmotor 17.

FIG. 4 shows the operation of selected components of a vehicle drivesystem in a third operating mode where torque distribution is performedby the internal combustion engine 11 and the electric wheel motors 17 inaccordance with one embodiment of the present invention. Under certainconditions it may be desirable to provide torque for rotating the wheels13, 18 from both the internal combustion engine 11 and the electricwheel motors 17. For example, it may be preferable for the vehicle toengage the third operating mode when the vehicle is operated at a speedgreater than a predetermined speed. The predetermined speed may be setby a manufacturer or a user. Additionally, the predetermined speed maybe set according to driving conditions, driving habits, road conditions,or a combination thereof.

FIG. 4 shows a combination of the vehicle systems shown in FIGS. 2 and3. The control unit 20 controls the electric wheel motors 17 to couplethe axle shaft 22 with the axle stub 23 via the clutch unit 25 when thevehicle is in the third operating mode. Additionally, the control unit20 controls the electric wheel motors 17 to provide torque to the wheels13, 18 via the axle stub 23. Furthermore, the internal combustion engine11 may simultaneously provide torque to the axle shaft 22 via the outputshaft 15 which are both coupled to the differential 16.

Similar to the second operating mode, the control unit 20 may vary theamount of torque applied to each wheel 13, 18 via the electric wheelmotor 17. Preferably, the control unit 20 varies the amount of torqueapplied to each wheel 13, 18 according to at least one of a userselection, a driving condition, a road condition, and a user's drivinghabits. While in the third operating mode, the internal combustionengine 11 may act as a generator to produce electricity to be stored inthe power storage unit 28 and provided to the electric wheel motor 17.

In addition to varying the amount of torque applied to each wheel 13,18, the control unit 20 may control each electric wheel motor to reduceor stop the rotation of each respective wheel 13, 18. Thus, the controlunit 20 may control each electric wheel motor 17 to act as a traditionalbrake such that the vehicle drive system may bypass, assist, oreliminate the use of a traditional braking mechanism. Additionally, inan alternate embodiment of the present invention, the electric wheelmotors may house a planetary transmission which may be controlled by thecontrol unit 20 in the third operating mode.

FIG. 5 illustrates an alternate embodiment of the vehicle drive assemblywith which the electric wheel motors 17 may be coupled with wheels 13,18 in accordance with one embodiment of the present invention. As shownin FIG. 5, the vehicle drive assembly includes an internal combustionengine 11 with a conventional transmission system 12. A transfer unit 54is coupled with the transmission system 12. The internal combustionengine 11 provides driving torque to the wheels 13 via an output shaft15 coupled to the transfer unit 54 and the differential 16.Additionally, the internal combustion engine 11 provides driving torqueto the wheels 18 via a second output shaft 52 which is coupled to thetransfer unit 54 and the second differential 51.

The output shaft 15 provides torque to the axle shaft 22 via thedifferential 16. The axle shaft 22 may be selectively coupled to theaxle stub 23 via a clutch unit 25 housed in the electric wheel motor 17.The coupled axle shaft 22 and axle stub 23 comprise the coaxial shaft 14as shown in FIG. 1.

The second output shaft 52 provides torque to the second axle shaft 53via the second differential 51. The axle shaft 53 may be selectivelycoupled to an axle stub 23 via a clutch unit 25 housed in the electricwheel motor 17. The coupled axle shaft 53 and axle stub 23 comprise acoaxial shaft 55.

The differentials 16, 51 may be conventional differentials for providingdesired torque distribution to the wheels 13, 18, respectively. Theoutput shaft 15, 52 may provide driving torque to wheels 13, 18,respectively depending on an operative condition of the coupling unit,which selectively couples the axle shafts 22, 53 to respective axlestubs 23.

In accordance with the present invention, the system shown in FIG. 5 mayinclude various operating modes. For example, torque may be provided forrotating the wheels 13, 18 exclusively from the electric wheel motors17. Alternatively, torque may be provided for rotating the wheels 13, 18exclusively from the internal combustion engine 11. Furthermore, torquefor rotating the wheels 13, 18 may be provided from both the internalcombustion engine 11 and the electric wheel motors 17. The variousoperating modes discussed above are similar to the operating modesdiscussed with respect to FIGS. 2-4. Therefore, discussion of theseoperating modes will be omitted with respect to FIG. 5.

As described above, the present invention provides various effects oradvantages. For example, vehicle performance may be controlledelectronically via an electric wheel motor. Thus, because electric wheelmotor parts are smaller and cheaper to manufacture, costs are reduced.Costs are also reduced since the combustion engine, drivetrain, andelectric wheel motors may be used in various configurations to meet thespecific needs of a customer. Moreover, use of electric wheel motorsimprove vehicle efficiency. Specifically, the electric wheel motorsreduce fuel costs and allow for improved performance of the internalcombustion engine since the internal combustion engine may be tailoredto perform in a narrow speed range.

Although the present invention may be implemented using the exemplaryseries of operations described herein, additional or fewer operationsmay be performed. Moreover, it is to be understood that the order ofoperations shown and described is merely exemplary and that no singleorder of operation is required.

The foregoing embodiments and advantages are merely exemplary and arenot to be construed as limiting the present invention. The presentteaching can be readily applied to other types of apparatuses andprocesses. The description of the present invention is intended to beillustrative, and not to limit the scope of the claims. Manyalternatives, modifications, and variations will be apparent to thoseskilled in the art.

1. A vehicle drive assembly, comprising: an engine; a transmissionoperably coupled with the engine; an output shaft operably coupled withthe transmission, wherein the output shaft rotates according to anoperation between the engine and the transmission; a differentialoperably coupled with the output shaft; an axle shaft rotatably coupledto the differential, wherein the axle shaft is rotated by thedifferential when the output shaft rotates; at least one wheelselectively coupled to the axle shaft via a rotatable axle stub whereinthe at least one wheel is rotated according to a rotation of the axleshaft when the axle shaft is operably coupled to the axle stub; anelectric wheel motor operably coupled to the at least one wheel via therotatable axle stub, wherein the at least one wheel is rotated when theelectric wheel motor provides a torque to the rotatable axle stub; and acoupling device operably coupled with the electric wheel motor forselectively coupling the axle stub with the axle shaft, wherein when theaxle shaft is not coupled to the axle stub, the at least one wheelcannot be rotated by the engine via the axle shaft.
 2. The vehicle driveassembly of claim 1, further comprising a power storage medium providingpower to the electric wheel motor.
 3. The vehicle drive assembly ofclaim 1, further comprising a controller for controlling the vehicledrive assembly according to at least one of: a first mode wherein thecoupling device uncouples the axle shaft from the axle stub and theelectric wheel motor alone provides torque to the axle stub to rotatethe at least one wheel; a second mode wherein the engine alone providestorque to the axle stub via the axle shaft to rotate the at least onewheel; and a third mode wherein both the electric wheel motor and engineprovide torque to the axle stub to rotate the at least one wheel.
 4. Thevehicle drive assembly of claim 3, wherein the controller controls thevehicle drive assembly according to the first mode when a vehicle speedis less than a predetermined speed.
 5. The vehicle drive assembly ofclaim 3, wherein the controller controls the vehicle drive assemblyaccording to the second mode and third mode when a vehicle speed isgreater than a predetermined speed.
 6. The vehicle drive assembly ofclaim 3, wherein the controller controls the amount of torque outputfrom the electric wheel motor.
 7. The vehicle drive assembly of claim 6,wherein the amount of torque output from the electric wheel motor variesaccording to at least one of a driver selection, a road condition, and adriving condition.
 8. The vehicle drive assembly of claim 3, wherein thecontroller controls the operation of the engine in a fourth mode suchthat the engine functions as a generator for a power storage mediumproviding power to the electric wheel motor.
 9. The vehicle driveassembly of claim 3, wherein the electric wheel motor supplies a forceto the axle stub to reduce the rotation of the at least one wheel in thefirst mode, second mode, or third mode.
 10. The vehicle drive assemblyof claim 3, wherein the electric wheel motor further comprises aplanetary gearset for operation in the third mode.
 11. A vehicle driveassembly, comprising: an engine; a transmission operably coupled withthe engine; a transfer unit operably associated with the transmission; arear output shaft operably coupled with the transfer unit, wherein therear output shaft rotates according to an operation between the engine,the transmission, and the transfer unit; a front output shaft operablycoupled with the transfer unit, wherein the front output shaft rotatesaccording to an operation between the engine, the transmission, and thetransfer unit; a front differential operably coupled with the frontoutput shaft; a rear differential operably coupled with the rear outputshaft; a front axle shaft rotatably coupled to the front differential,wherein the front axle shaft is rotated by the front differential whenthe front output shaft rotates; a rear axle shaft rotatably coupled tothe rear differential, wherein the rear axle shaft is rotated by therear differential when the rear output shaft rotates; at least one frontwheel selectively coupled to the front axle shaft via a front rotatableaxle stub wherein the at least one front wheel is rotated according to arotation of the front axle shaft when the front axle shaft is operablycoupled to the front axle stub; at least one rear wheel selectivelycoupled to the rear axle shaft via a rear rotatable axle stub whereinthe at least one rear wheel is rotated according to a rotation of therear axle shaft when the rear axle shaft is operably coupled to the rearaxle stub; an electric wheel motor operably coupled to the at least onefront wheel via the front rotatable axle stub, wherein the at least onefront wheel is rotated when the electric wheel motor provides a torqueto the front rotatable axle stub; and a coupling device operably coupledwith the electric wheel motor for selectively coupling the front axlestub with the front axle shaft, wherein when the front axle shaft is notcoupled to the front axle stub, the at least one front wheel cannot berotated by the engine via the front axle shaft.
 12. The vehicle driveassembly of claim 11, further comprising a power storage mediumproviding power to the electric wheel motor.
 13. The vehicle driveassembly of claim 11, further comprising a controller for controllingthe vehicle drive assembly according to at least one of: a first modewherein the coupling device uncouples the front axle shaft from thefront axle stub and the electric wheel motor alone provides torque tothe front axle stub to rotate the at least front one wheel; a secondmode wherein the engine alone provides torque to the front axle stub viathe front axle shaft to rotate the at least one front wheel; and a thirdmode wherein both the electric wheel motor and engine provide torque tothe front axle stub to rotate the at least one front wheel.
 14. Thevehicle drive assembly of claim 13, wherein the controller controls thevehicle drive assembly according to the first mode when a vehicle speedis less than a predetermined speed.
 15. The vehicle drive assembly ofclaim 13, wherein the controller controls the vehicle drive assemblyaccording to the second mode and third mode when a vehicle speed isgreater than a predetermined speed.
 16. The vehicle drive assembly ofclaim 13, wherein the controller controls the amount of torque outputfrom the electric wheel motor.
 17. The vehicle drive assembly of claim16, wherein the amount of torque output from the electric wheel motorvaries according to at least one of a driver selection, a roadcondition, and a driving condition.
 18. The vehicle drive assembly ofclaim 13, wherein the controller controls the operation of the engine ina fourth mode such that the engine functions as a generator for a powerstorage medium providing power to the electric wheel motor.
 19. Thevehicle drive assembly of claim 13, wherein the electric wheel motorsupplies a force to the front axle stub to reduce the rotation of the atleast one front wheel in the first mode, second mode, or third mode. 20.The vehicle drive assembly of claim 11, further comprising: a rearelectric wheel motor operably coupled to the at least one rear wheel viathe rear rotatable axle stub, wherein the at least one rear wheel isrotated when the rear electric wheel motor provides a torque to the rearrotatable axle stub; and a rear coupling device operably coupled withthe rear electric wheel motor for selectively coupling the rear axlestub with the rear axle shaft, wherein when the rear axle shaft is notcoupled to the rear axle stub, the at least one rear wheel cannot berotated by the engine via the rear axle shaft.
 21. A vehicle driveassembly, comprising: an engine; a transmission operably coupled withthe engine; a transfer unit operably associated with the transmission; arear output shaft operably coupled with the transfer unit, wherein therear output shaft rotates according to an operation between the engine,the transmission, and the transfer unit; a front output shaft operablycoupled with the transfer unit, wherein the front output shaft rotatesaccording to an operation between the engine, the transmission, and thetransfer unit; a front differential operably coupled with the frontoutput shaft; a rear differential operably coupled with the rear outputshaft; a front axle shaft rotatably coupled to the front differential,wherein the front axle shaft is rotated by the front differential whenthe front output shaft rotates; a rear axle shaft rotatably coupled tothe rear differential, wherein the rear axle shaft is rotated by therear differential when the rear output shaft rotates; at least one frontwheel selectively coupled to the front axle shaft via a front rotatableaxle stub wherein the at least one front wheel is rotated according to arotation of the front axle shaft when the front axle shaft is operablycoupled to the front axle stub; at least one rear wheel selectivelycoupled to the rear axle shaft via a rear rotatable axle stub whereinthe at least one rear wheel is rotated according to a rotation of therear axle shaft when the rear axle shaft is operably coupled to the rearaxle stub; an electric wheel motor operably coupled to the at least onerear wheel via the rear rotatable axle stub, wherein the at least onerear wheel is rotated when the electric wheel motor provides a torque tothe rear rotatable axle stub; and a coupling device operably coupledwith the electric wheel motor for selectively coupling the rear axlestub with the rear axle shaft, wherein when the rear axle shaft is notcoupled to the rear axle stub, the at least one rear wheel cannot berotated by the engine via the rear axle shaft.
 22. The vehicle driveassembly of claim 21, further comprising a power storage mediumproviding power to the electric wheel motor.
 23. The vehicle driveassembly of claim 21, further comprising a controller for controllingthe vehicle drive assembly according to at least one of: a first modewherein the coupling device uncouples the rear axle shaft from the frontaxle stub and the electric wheel motor alone provides torque to the rearaxle stub to rotate the at least front one wheel; a second mode whereinthe engine alone provides torque to the rear axle stub via the rear axleshaft to rotate the at least one rear wheel; and a third mode whereinboth the electric wheel motor and engine provide torque to the rear axlestub to rotate the at least one rear wheel.
 24. The vehicle driveassembly of claim 23, wherein the controller controls the vehicle driveassembly according to the first mode when a vehicle speed is less than apredetermined speed.
 25. The vehicle drive assembly of claim 23, whereinthe controller controls the vehicle drive assembly according to thesecond mode and third mode when a vehicle speed is greater than apredetermined speed.
 26. The vehicle drive assembly of claim 23, whereinthe controller controls the amount of torque output from the electricwheel motor.
 27. The vehicle drive assembly of claim 26, wherein theamount of torque output from the electric wheel motor varies accordingto at least one of a driver selection, a road condition, and a drivingcondition.
 28. The vehicle drive assembly of claim 23, wherein thecontroller controls the operation of the engine in a fourth mode suchthat the engine functions as a generator for a power storage mediumproviding power to the electric wheel motor.
 29. The vehicle driveassembly of claim 23, wherein the electric wheel motor supplies a forceto the rear axle stub to reduce the rotation of the at least one rearwheel in the first mode, second mode, or third mode.
 30. The vehicledrive assembly of claim 21, further comprising: a front electric wheelmotor operably coupled to the at least one front wheel via the frontrotatable axle stub, wherein the at least one front wheel is rotatedwhen the front electric wheel motor provides a torque to the frontrotatable axle stub; and a front coupling device operably coupled withthe front electric wheel motor for selectively coupling the front axlestub with the front axle shaft, wherein when the front axle shaft is notcoupled to the front axle stub, the at least one front wheel cannot berotated by the engine via the front axle shaft.